Cash register



April 11, 1939. J. H. GRUVER 2,154,381

CASH REGISTER Filed Dec. 6, 1935 4 Sheets-Sheet 3 FIG. 15

3nventor John H. Gruver Hh attorney April 1, 1939. J. H. GRUVER 2,154,381

' CASH REGISTER Filed Dec. 6, 1935 4 Sheets-Sheet 4 FIG. 13

Zinnentor John H. Gruver Hi: Gttomeg Patented Apr. 11, 1939 UNITED. STATESv PATENT oar-ice CASH REGISTER Application December a, 1935, Serial No. 53,128

26 Claims.

This invention relates to cash registers and accounting machines and is directed particularly to a novel means for feeding record material a different distance during sub-total operations 5 from that which it receives during grand-total operations, and also has means coordinated with the feeding means to control the printing hammers for recording data on such record -mate rial.

10 The invention is shown applied to a machine of the type disclosed in Letters Patent Nos. 1,865,147 and 1,963,733, issued on June 28, 1932, and June '19, 1934, to Bernis M. Shipley and Samuel Brand, respectively. It is "to be under- 16 stood that the invention may be used with any other suitable type of machine, the particular machine illustrated being merely by way of example.

An object of this invention is to provide new 20 and novel means for controlling the feed given to the record material by the feeding mechanism thereof.

A more particular object is to provide means for feeding the record material a short distance 25 during sub-total operations by controlling the feeding mechanism, which feeds the record material a greater distance during grand-total operations.

Another object is to provide means for preventing the issuance of the receipt from the machine when printing thereon a sub-total of an item or plurality of items comprising a transaction, in order that the operator may read such sub-total off the indicators and calculate the tax thereon, and for automatically issuing the receipt from the machine when the grand total for the complete transaction, which includes such tax, is printed thereon.

A further object is to provide means for automatically disabling the special data printing hammers during sub-total operations.

A still further object is to provide means for automatically releasing the special data printing 45 hammers when printing grand totals.

With these and incidental objects in view, the invention includes certain novel features of construction and combinations of parts, the essential elements of which are set forth in appended 50 claims and a preferred form or embodiment of which is hereinafter described with reference to the drawings which accompany and form a part of this specification.

! said drawings:

55 Fig. 1 is a section taken along side of one of the amount banks, showing the mechanism for controlling the indicating mechanism.

Fig. 2 is a side view of a portion of the total control lever and the means by which it controls the amount of feed to be given to the receipt paper during sub-total and grand-total operations.

Fig. 3 is a diagrammatic view of the keyboard of the machine.

Fig. 4 is a facsimile of the type of receipt issued by the machine.

Fig. 5 is a facsimile of a portion of the detail strip printed by the machine.

Fig. 6 is a detail side view of the upper printing hammers and the mechanism for controlling 16 the extent of feed given to the receipt paper.

Fig. '7 is a detail side view of a portion of the mechanism for operating the upper printing hammers.

Fig. 8 is a detail side view of the mechanism for operating the lower printing hammer.

Fig.9 is a detail side view of the means for altering the control exercised by the mechanism for determining the extent of feed to be given to the receipt paper.

Fig. 10 is a detail side view of the means for controlling the feeding mechanism toieed the receipt paper a short distance during sub-total operations and a longer distance during grandtotal operations.

Fig. 11 is a detail side view of the flexible drive for the receipt feeding control member.

Fig. 12 shows a side view oi. the mechanism for changing the machine froma single cycle to a double cycle operation.

Fig. 13 is a perspective view of the printing hammer control lever and the means by which it disables the upper printing hammers.

Fig. 14 is a top plan view of the flange and its extension on the printing hammer control lever and the studs with which they ccact to disable certain of the upper printing hammers.

Fig. 15 is a detail side view of the gear segment for operating the feeding mechanism for the receipt paper, showing the various positions which the stud assumes for cohtrolling the extent of movement of such gear segment.

Fig. 16 is a detail side view of the latch for holding the hammer control means in a certain one of its moved positions.

Gunman. Dascnrrnon Previous to this time, machines of the type herein referred to were only capable of printing on a receipt a single item or a plurality of items 66 pable of printing a single total on the receipt,

before automatically feeding it from the machine. It was also customary in such machines,

when printing the total, to simultaneously therewith print the consecutive number, date and other desired data. 1

In the many places of business handling tax-' able goods today it has been found desirable to have such machines print on the receipt, in addition to the items comprising a transaction, a sub-total thereof, the amount of tax to be charged, such tax to be calculated by the operator on the sub-total amount displayed by the indicating mechanism, and the grand total amount for the complete transaction, before the receipt paper is automatically fed from the machine in the form of a receipt to be given to the customer.

In accomplishing the above desired results, it is necessary that the printing hammers which print the consecutive number, date and other desired data, which hammers ordinarily print during total taking operations, be disabled during sub-total operations and then released for operation during grand total operations.

The present invention contemplates means for accomplishing all of the desired results mentioned above, which means will be hereinafter described in detail.

DETAILED Dascarr'non Keys and diflerential mechanism The keyboard and differential mechanism of the present application is substantially like that shown and illustrated in the previously mentioned Shipley Patent No. 1,865,147, and reference may be made thereto for a complete disclosure and description thereof. Only a brief description of the keyboard and its cooperating mechanism will, therefore, be given herein.

The keyboard (Fig. 3) comprises four banks of amount keys 30, one bank of clerks keys Si.

a bank of transaction or classification keys 32, a starting key 33, and a total lever N (Fig. 2) for controlling the machine for sub-total and grand-total taking operations.

For the sake of clearness, the captions Read" and "Reset on the keyboard illustrated in Fig. 3, which represent the positions to which the total lever 34 is moved for conditioning the machine for total taking operations, will hereinafter be referred to as sub-total" and grand-total, respectively.

The bank of transaction keys 3! has associated therewith a differential similar to that hereinafter described in connection with the amount bank of keys 30, except that the teeth thereon are omitted, for setting a type wheel having characters corresponding to these keys to indicate on the receipt and record strip the character of the transaction recorded. The clerks keys 31 are adapted to directly set a type wheel associated therewith, having characters corresponding to these keys, to print on the receipt and record strip a character indicating the clerk handling the transaction. The total lever 84 sets a special character type wheel associated therewith, when the lever is moved to either its sub-total or grand-total position, to print a character to indicate whether the total printed is a sub-total or a grand total. Since these mechanisms form no part of the present invention, no disclosure thereof is made in this application.

The only diiferential' mechanism described hereinisthatforoneofthebanksofammint No. 1,865,147. Inasmuch as this mechanism is old and well known in the art, only a brief description thereof will be given here.

The keys (Pig. 1) of each amount bank are mounted in an individual frame II mounted on rods It and 31, carried by the side frames of the machine, only the left-hand side frame 4| being shown. The keys are retained in their normal outer positions by the usual compression springs (not shown). The keys II cooperate with a detent. ll supported at its upper end by an arm I! and at its lower end by an arm 4., which arms are supported on studs in the frame ii. The detent 38 has a pin 4| for each key imits associated bank, and when a key is depressed its associated pin 4| moves the detent downwardly until a shoulder 42 on the key passes the pin ll whereupon the detent a is raised slightly, by a spring 43, one end of which is attached toastudonanarmflsecuredtoaahaft", and the other end to a stud on the key frame II. Anarmflisalsosecuredtotheahaftll and has a stud 41 which contacts the arm 4.. The spring 0 constantly urges the arms I and It clockwise and, through the stud 41, urges the arm ll counter-clockwise to elevate the detent 38. Thus, when a key II is depressed, its corresponding stud ll is moved over the shoulder 42 of the key to retain the key in a depressed position.

When a key is depressed and the arm ll thereby rocked clockwise, it will, through its engagement with the stud 41, rock a zero stop pawl ll, secured to the shaft 45, counter-clockwise out of the path of movement of the diilerential mechanism to be hereinafter described, thus permitting the diii'erential latch to contact the inner end of the depressed key and thereby stop the differential mechanism. In this manner the amount keys control the setting of the amount differential mechanism.

There is a differential unit for each of the amount key banks. Each unit is supported by two hangers I (only one of which is shown) mounted upon rods 8 and IT. A rod 58 extends through all of the differential units, and acts as a' stabilizer for said units.

Each differential unit (Fig. 1) is driven by a pair of cams 5! and OI fixed on a main operating shaft H. These cams cooperate with rollers i2 and II, respectively, on a Y-shaped lever N pivoted on a stud ii on the hanger I.

The upper end of the lever 84 is connected by a link 8 to a driver "I loose on a hollow stud N fastened in the hanger II. The clockwise movement of the cams II and 60 during an add operation oscillates the lever 64 first clockwise and then counter-clockwise to normal position. This movement, through the link it, rocks the driver 61 first clockwise and then counter-clockwise to its normal position.

For each unit, there is a differential actuator N having a hub HI journaled on the stud 88. Each differential actuator is carries three separate segments H which operate totaliser pinions II of three totallzer lines in order to register the amount represented by a depressed key in any of the totalizers which may have been selected. The differential actuator n is connected to the above a shoulder II, by a spring 19. Forthe purpose of unlatching the latch 19 from the driver 91 tosaidactuator. Afoot ll ofthelatch'llis normally held in engagement with the driver, 91,

there is pivoted on the actuator 99 a bell'crank .11, one end of which is pivoted to a link". The link I9 is pivoted at one end to the latch I9 while its free end bears the shape of a locking nose 19.

By this latch connection, the actuator 99 and segments II are rotated clockwise during an operation of the machine until the free end of the bell crank 11 strikesthe end of a depressed key. When this occurs, the bell crank 11 and link 19 are moved counter-clockwise thereby disengaging the foot 14 on the latch II from the shoulder 19 on the driver 61. The foot ll then rides upon the outer peripery of the driver 91 as the driver continues its invariable movement. When the latch is thus disengaged, the nose I9 on the link 19 engages a notch 99, opposite the depressed key, in a latch retaining bar 9| mounted at its lower end on the rod 56 and at its upper end on the hanger 99. There are ten notches 99 in the latch retaining bar 9i, one for each of the nine keys in the bank and one at the zero position. When there is no amount key depressed, the latch is disengaged in the zero position by the zero stop pawl 49.

There is provided a reset spider 92 (only a portion of which is shown), which is the usual and well known reset spider for controlling the differential positioning of the actuator 99 during reset operations to set the amount taken from the totalizer wheels on the indicators and the type wheels in the customary manner, as shown in the Shipley Patent No. 1,865,147, above referred to. It is through this means that the.sub-total of a plurality of items comprising a transaction is set up on the indicators, thereby displaying to the operator the proper amount upon which the tax is to be computed.

As before mentioned, the present invention provides means for controlling the feed of the receipt paper so that both a sub-total and a grand total may be printed thereon, before it is automatically fed from the machine in the form of a receipt.

It is thus possible for the operator, after a subtotal is printed on the receipt paper and set up on the indicators by means of the reset spider above referred to, to compute the tax on the amount thus displayed by the indicators and enter the proper amount of the tax on the machine, which amount is printed on the receipt paper. A grand total is then taken, which amount is printed on the receipt paper, after which the paper is automatically fed out of the machine in the form of a receipt.

Since the function and operation of the reset spider 82 is fully shown and described in the above mentioned Shipley patent, no further description thereof will be given herein.

When the driver 91 is rotated counter-clockwise to its home position, a shoulder 93 thereon contacts a'pin 94 on the actuator 69 and restores it and the segments II to their normal positions. The time when the driver 61 contacts the pin 94 varies according to the key which has been depressed. If the "2 key has been depressed, the driver 91 does not contact the pin 94 until near the end of its counter-clockwise movement. However, if the 9" key has been depressed and the latch 19 disengaged at the "9 position, the shoulder 93 immediately contacts the pin 94 upon the return, movement of the driver .1, thereby causing a greater rotation of whichever totaliaer wheel 'll whichhasbeenpreviouslyengagedwith any one ofthe segments Ii.

Thetotalizerwheelsfl arerockedintoen- Basement with the segments ll, during adding operations, after the latches 19 have been disengaged from the drivers 91, so that, as the segments Ii are returned to their normal positions, the

amounts, as determined by the depressed keys, are

accumulated on the totalizer wheels.

In the present machine, totals are taken in accordance with the well known principle that the totalizer wheels II should be coupled to the actuator segments II atthe beginning of their advance movement, so that the arrival of the totalizer wheels at zero will set the actuator segments II at positions corresponding with the total standing on the totallzer, whereby the indicating mechanism and the printing devices are set from the segments Ii to indicate and print such total. If the total is to be a grand totaLthe totalizer wheels are to remain at zero or be cleared, and therefore such wheels would be uncoupled from the actuator segments II at the completion of the advance of the latter. If, however, a sub-total is to be taken,' the total is to remain in the totalizer and, therefore, the totalizer wheels remain coupled to the actuatorsegments 'Il during the advance and return strokes, so that the total is set up again in the totalizer, after the actuator segments II have been'set, to indicate and print the total, during their advance strokes. Inasmuch as the mechanism for accomplishing this result is shown and described in the patent to Bernis M. Shipley, No. 1,817,883, issued August 4, 1931, no illustration or detailed description thereof is given herein.

DiperentiaL-transjer or carrying The carrying mechanism in this case is identical with the carrying mechanism illustrated and described in the above mentioned Shipley Patent No. 1,865,147. It has been only partially illustrated here and will be but very briefly described.

Associated with each of the segments II is a two-toothed segment-arm 99 (Fig. 1) pivoted to the actuator 99. Considering now the segment H and segment-arm 99 associated with the upper totalizer line, when the segment 1| is rocked clockwise it closes the gap between itself and the segment-arm 99, thus permitting that segmentarm to be positively coupled to the segment II by a lever 94, in a manner fully described in the Shipley Patent No. 65, 7, above referred to. As the segment II is moved counter-clockwise to its home position, if no carry has taken place, the two-toothed segment-arm 93 is stopped in the position shown in Fig. 1 by means not shown. If, however, a carry has taken place, this segment-arm moves one step farther in a counterclockwise direction before it is stopped, thus causing "one" to be added into the totalizer pinion, in addition to the amount added under the control of the amount keys.

Associated with each differential unit is a beam 95 (Fig. 1) pivoted at 96 to the actuator 99. The beam 95 is slotted to receive a stud 91 on a link 99, the upper end of which is connected to a segment I99 associated with the indicating mechanism. One segment I 99' is mounted on a shaft I93 and the remaining segments for the other differential units are carried by nested sleeves I04. The lower end of the link is pivoted to an arm IOI, which is connected to the printing mechanism.

As previously described, the lever 04 through the link 60 and driver 01, drives the actuator 40 until the latch 13 is disengaged from the driver 01, either by the zero stop pawl 40 'or the end of a depressed amount key. This movement of the actuator 80 positions the left end of the beam 95 accordingly. The lever 04 carries a roller I02, which, when the lever 04 is rocked clockwise, contacts the under side of the beam and moves the beam 05 about its pivot 06 until its upper edge contacts the hub on the actuator 59, thereby positioning the right end of the beam 05 and, consequently, the link 90, segment I00 and arm IN, to set the indicating mechanism and type wheels .according to the value of the key depressed.

Indicators The indicating mechanism disclosed in connection with the present machine is substantially the same as that fully illustrated and described in United States Letters Patent No. 1, 63,748, issued to F. L. Fuller December 14, 1915. Therefore,

but a brief description of it will be given herein.

As before mentioned, it is the indicating mechanism that furnishes the operator with the amount upon which the tax is to be computed, such amount being a sub-total of the items comprising the tran'saction. The operator then calculates the proper tax on such amount, enters the tax on the machine, after which the tax is shown on the indicating mechanism and printed on the receipt paper. A grand total is then taken of the complete transaction and printed on the receipt paper, immediately after which the paper is automatically fed out of the machine in the form of a receipt.

There are two groups of indicators I00 (Fig. l) for each bank of keys in the machine, one group indicating at the front of the machine and. the other group indicating at the back of the machine.

As all of these indicators are similarly mounted, a group associated with one of the amount banks only is illustrated and described herein.

The groups of indicators I08 are carried in a carriage I08 and rest upon ledges I I0 of a runner III slidably mounted on rollers II2 on rods II3 supported by two frames II4 (only one of which is shown), one at each end of the machine. Theframes II4 are secured to the side frames of the machine by screws I I5. The runner I II has teeth II6 meshing with a segment III integral with the segment I00 differentially positioned through the link 88 by the differential mechanism. In this manner, the carriage I00, carrying the groups of indicators I08, is differentially positioned to bring any desired indicator I08 into operative relation with an indicator lifting means to be hereinafter described.

As the indication from the back of the machine is the reverse of that looking from the front, all the various groups of front and back indicators cannot be mounted on runners similar to runner-I I I, but must be carried by separate runners and the back indicators differentially positioned from the segments 1, which operate the corresponding front indicators by the sleeves I04 which carry segments similar to segments III in mesh with racks formed in the back indicator runners.

Indicators-408 The indicator lifting mechanism is substantially the same as that shown and described in the above mentioned Fuller Patent No. 1,183,748. After the indicator carriages have been differentially positioned according to the keys depressed. the selected indicators are exposed to view by a frame I I0 having projections I at the front and back thereof, and adapted to raise the selected indicators to view. Before the carriages III are differentially positioned, the indicators exposed during the previous operation are lowered to their normal positions by lowering the frame III.

Indicatorsalianing mechanism Suitable aligning mechanism is provided for properly aligning the indicators,- but inasmuch such mechanism is shown and described in the above mentioned Fuller Patent No. 1,163,748, only a small portion of that mechanism is shown herein. Each of the segments I00 has aligning notches I2I with which cooperates an aligning bar I22 screwed to a pair of armsl20 (only one of which is shown here) pinned on a shaft I24. The shaft I24 is operated by means, not shown here but fully illustrated and described in the above mentioned Fuller patent, to withdraw the aligning bar I22 from the segments I00 so that they may be differentially positioned under the control of the differential mechanism, and then to again engage the bar with the segments to hold them in proper positions until a subsequent operation of the machine.

There is also another aligning mechanism which directly aligns the runners III of the indicator carriages I09. This aligner I25 is in the form of an angle-iron. The aligner I25has a slot in alignment with each runner I I I which guides the runner in its movements, and also has an aligning tooth I26 which cooperates with teeth I21 formed in the runner I I I. The aligner I25 is secured to a pair of arms I20 (only one of which is shown) pivoted on studs I29 mounted in the plates II4. Pivoted to the arms I28 are links I00 pivoted to arms (not shown) secured to the shaft I24 which causes the two aligning members to operate in unison.

PRINTING Msonsnrsx Type wheel setting The printing mechanism is located on the lefthand side of the machine proper, as is customary in machines of the type here referred to. A series of nested sleeves I (Fig. 1) mounted on a shaft I39, the sleeves being actuated by their associated arms IOI and controlled by the differential mechanism, as previously described, support at their left-hand ends segments I4I (Fig. 9) which mesh with teeth I42 of segment levers I 43 freely mounted upon a rod I44 extending between the two machine side frames 49 and the printer side frame I3I. The upper ends of the segment levers I43 have teeth I45 meshing with teeth I40 of partial gears I41 secured to nested sleeves I40 (Figs. 6 and 9) on a shaft I49 supported by the machine side frame 49 and printer side frame I3 I. Secured to the left-hand ends of the sleeves I40 and shaft I49 (Fig. 6) are type printing wheels I55, only one of which is shown. Each type wheel I has two sets of type characters to permit impressions being taken from the upper and lower sides of the wheels. The upper set prints upon an issuing receipt I31 and the lower set upon a record strip I00.

After the printing wheels I55 are moved to their respective positions, under control of the differential mechanism, they are retained in alignment, at the time the printing takes place,

by aligning arms (not shown) which engage the teeth I56 formed on the upper sides of the partial gears I41 (Fig. 9)

Reeeipt paper As before mentioned, the present machine is adapted to print and issue a receipt I31 (Figs. 4

and 6) containing the date, consecutive number, amount of each item comprising the transaction, a subtotal thereof, amount of tax charged, grand total for the complete transaction, symbols indicating whether a total is a sub-total or a grandtotal, characters representing the class of each item, a letter indicating the clerk handling the transaction, the words Total shown above and other selected data.

The receipt paper I31 (Fig. 4) is fed from a supply roll I51 (Fig. 6), carried on a stud I58 supported in the printer side frame I3I, around a roller I59, between impression hammers (later described) and the various type wheels I55, between a feed roller I60 and a tension roller and past a severing plate, said tension roller and severing plate not being shown herein, as they are fully illustrated and described in the above mentioned Shipley Patent No. 1,817,883.

Record strip In addition to the receipt I31, the machine prints on and retains in the machine a record strip I38 (Figs. 5 and 6). The record strip has printed thereon the amount of each item comprising a transaction, a sub-total thereof, the amount of tax charged, the grand total for the complete transaction, consecutive number, characters representing the class of each item, letter indicating clerk handling the transaction, and symbols indicating whether a total is a sub-total or a grand-total.

The record strip I38 (Fig. 6) is fed from a supply roll 260 around guide rollers 26I and between a lower printing hammer and the type wheels and onto a receiving roll 262, which is rotated in a counterclockwise direction by mechanism not shown here, but fully illustrated and described in the above mentioned Shipley Patent No. 1,865,147.

Ink ribbon For the purpose of making legible impressions upon the issuing receipts I31 and the record strip I36, an ink ribbon 263 (Fig. 6) is'provided. The

ink ribbon is fed from a supply roll 264 around guide rollers 265 in a manner to permit impressions being taken from both the upper and lower sets of type characters on the printing wheels I55. The ink ribbon 263 is wound upon a receiving roll 266. Inasmuch as the mechanism for feeding the ink ribbon is not pertinent to the present invention, it will suffice to say that any suitable type of feeding means therefore may be used.

Receipt paper feeding mechanism As heretofore mentioned, the present invention contemplates feeding the receipt paper I31 in a manner to permit printing thereon an item or plurality of items comprising a transaction, 9. sub-total thereof, the amount of tax to be charged, and the grand total, together with the consecutive number, date and other desired data,

before the receipt is automatically fed from the machine.

In previous machines of the type herein referred to, whenever any kind of total ,was printed on the receipt, the receipt was immediately thereafter automatically fed from the machine. However, the present invention provides means for feeding the receipt paper'in a manner to permit printing of both a sub-total and a grand total on the same receipt, before it is automatically fed from the machine. The feeding mechanism and means for controlling the same for feeding the receipt paper in the above mentioned manner will now be described.

The receipt feed roller I60 (Figs. 6 and 9) is loosely mounted upon a stud I6I supported at one end in the printer frame I3I. Secured to the feed roller I60 is a ratchet I62 engaged by a feed pawl I63 freely mounted on a stud I64 carried by an arm I65 loosely mounted upon the stud I6I. The pawl I63 is held in contact with the ratchet I62 by a spring I66 and moves the feed roller I60 clockwise to feed the receipt into its various printing positions. A spring actuated pawl I12 (Fig. 6) mounted on a stud I13 prevents retrograde motion of the feed roller I60. Secured to the feed arm I65 and moving freely on the stud I6-I is a pinion I14 in mesh with a gear segment I15. on the type wheel sleeves I48 and is normally urged in a clockwise direction by a spring I16 fast to a link I11 having one end pivoted to a rearwardly extending arm I18 formed on the segment I15.

Clockwise movement of the segment I15 causes it, through the pinion I14 meshing therewith and the arm I65 upon which the pawl I63 is carried, to move the feed roller driving pawl I63 counterclockwise around the ratchet wheel I63. Then when the segment I15 is moved counter-clock wise to its normal position, against the action of the spring I16, by a horizontally moving slide I19 (Fig. 9), it will cause the pawl I63 to move the feed roller I60 clockwise, thereby feeding the receipt paper I31 a. distance corresponding to the counter-clockwise movement of the feed roller driving segment I15. The slide I19 is pivoted at its right-hand end to the upper end of a lever I and is guided at its opposite end by a pin I8I projecting from .the printer side frame I3I through a slot I82 in said slide. When moving the drive segment I15 counter-clockwise to its normal position, the left-hand end of the slide I19 coacts with a pin I83 on the segment I15. The lever I80 is pivoted-on a rod I84 supported by the left side frame 49 of the machine and the printer side frame -I3I and has two arms carrying rollers I and ISI engaging cams I92 and I93, respectively, secured to a printer driv shaft I94. 1

During each cycle of operation of the machine, the cams I92 and I93 oscillate the lever I80 to first shift the slide I19 to the right, thereby permitting the segment I15 to be moved clockwise by the spring I16, and then shift the slide I19 toward the left to its'normal position, during which movement the end of the slide I19 contacts the pin I83 and moves the feeding roller driving segment I15 counter-clockwise to its home position, as shown in Figs. 6 and 9. Such counterclockwise movement of the segment I15 causes the pawl I63 to actuate the feed roller I60 clockwise, thereby feeding the receipt paper I31 a distance corresponding to the counter-clockwise movement of the drive segment I14.

The printing of items on the receipt during adding operations requires one cycle of operation of the machine, while the printing of any kind of total requires a two-cycle operation. During the first cycle of a two-cycle -operation, the receipt paper is given a short feed, and as the total is printed during the second cycle there will be a space between the last item and the total, as shown in Fig. 4.

Receipt paper feeding mechtmismm opertion During each adding operation, the slide I14 through the lever I is shifted first to the right and then to the left, as above mentioned. When the slide I19 is moved to the right. the segment I15 is rocked clockwise by the spring I14 until arrested by the inner edge of a projection Ill (Figs. 6, 9 and 15) formed on the segment I15 contacting a half-round stud I on an upwardly extending arm of a three-armed lever I81, such stud I96 normally projecting into an opening formed in the segment I15 by the projection I". The slide I19 then continues to move its full extent to the right, leaving the segment I" restrained by the stud I".

After the Printing takes place, the slide I12 moves idly toward the left until the end thereof contacts the stud I83 of the segment I15, whereupon continued movement of the slide I14 to the left rocks the segment I16 counter-clockwise until it is returned to its normal position. This counter-clockwise movement of the segment I" moves the pinion I14 and arm Ill clockwise about the stud I GI, and the feed pawl I coacts with a the ratchet wheels I to feed the roller III in a clockwise direction, thereby feeding the receipt paper I31 one step of movement. In this manner the receipt paper I31 is fed, during adding operations, one step of movement in order that each item of a multiple-item transaction can be printed in successive order thereon.

Receipt paper feeding mechanism sub-total operation After printing an item or a plurality of items comprising a transaction on the receipt paper I31, it is desired to print and indicate a sub-total thereof, in order that the proper amount of tax to be charged can be calculated from the subtotal amount which is conveniently displayed to the operator on the indicators Ill in the machine. As before mentioned. in previous machines of the type herein referred to, it was impossible to print on the receipt a sub-total, as well as indicate such sub-total amount, and still retain the receipt in the machine for the purpose of subsequently printing thereon the amount of tax calculated on the sub-total amount displayed by the indicators, followed by the printing of the grand total for the complete transaction, after which the receipt is automatically fed out of the machine in the customary manner. The present invention provides means for accomplishing these results, which means will be presently described.

The total lever 34 (Fig. 2) is provided with a slot 202 into which projects a pin 204 on a lever 205 pivoted at 206. Also pivoted at 206 is an arm 201 having a stud 208 which is normally held in contact with the upper end2ll0 of the lever 244 by a spring 2III. The lever 205 and arm 241 together form a slot 2| i into which projects a roller 2I2 onanarm 2H secured to ashaft2l4.

In Fig. 2, the total lever 34 is shown in its "add" position. Movement of the lever upwardly to take a sub-total, or downwardly to take a grand-total, through the cam slot 2", lever 244 and arm 201, rocks the arm 2i! and consequently the shaft 2 in a clockwise direction. Secured to the shaft 2 (Fig. 12) is an arm 224 connected by a link Hi to a lever 222 pivoted at 22!. Connected to the lever 222 is a pitman 224 slotted to surround a screw stud 22! mounted in the right side frame (not shown) of the machine. This pitman carries a roller 22 normally resting in an oifset 221 of a cam race 224 in a disk 22!. The pitman 224 also has two pins 224 projecting on either side of a flange 2II of a coupling slide 232, which is adapted to couple the cam disk 224 with a gear 2".

The clockwise movementgiven to the saft 2I4 by the total lever 44, through the connections shown in Fig. 2, moves the pitman 224 to the left to position the coupling slide 232 so that the cam disk 22! is coupled to the gear 222, in order that they will operate in unison. During either a subtotal or grand total operation, with the cam disk 22! thus coupled to the gear 238 so that they move together as a single unit, the shaft 2 l4 will receive a further clockwise movement near the end of the first cycle of operation of the machine to effect the release of certain of the printing hammers and move the stud I! (Fig. 15) out of the opening in the segment I15, thus freeing the segment I15 to be rocked clockwise to its fullest extent by the spring I1i. The manner in which the shaft 2 performs such results will now be described.

When the total lever 34 is moved from its add" position to either a sub-total or grand total position, it moves the shaft 2 I4 slightly clockwise, as previously described. When this occurs, an arm 24' (Fig. 9) fast on the shaft 2 moves a slide 24I supported at its free end by a printer control shaft 242. This slide 2 carries a roller 24! which coacts with an arm 244 fast on the printer control shaft 242 and moves the latter slightly clockwise. It is thus obvious that any clockwise movement given to the shaft 2 is, through the train of mechanism just described. transmitted to the printer control shaft 242.

The three-armed lever I41, heretofore referred to, loosely mounted on the shaft 242 controls, through its stud I, the extent of movement given to the segment I15 by the spring I14. which segment actuates the feed roller I" to feed the receipt paper various distances, depending upon the extent of movement given to the segment I14. Whenever the printer control shaft 242 is rocked clockwise, the three-armed lever I '1 is, by means to be presently described, rocked likewise.

A stud 244 (Fig. 11) on an arm 2" fast to the shaft 242 projects between a pair of arms 246 and 241 journaled on the shaft 242 and pressed against the stud 240 by a spring 248. A stud 24! (Figs. 10 and 11) on the threearmed lever I91 also projects between the arms 244 and 241. Clockwise movement of the shaft 242 and the arm 2" is transmitted by the stud 249 to the arm 244, thence through the spring 24! to the arm 241, which contacts the stud 24B to rock the three-armed lever Il1 clockwise. A spring actuated arm 25I fast to the shaft 242 serves to rock the shaft 242 counter-clockwise near the end of the second cycle of operation and, through the flexible drive connections -244--241, returns the three-armed lever I21 and its associated parts to their normal positions.

Thus when the total lever 94 ismoved from its add position to either its sub-total or "grand-total" position, it causes the three-armed lever I91, through the train of mechanism above described, to be rocked slightly clockwise. The purpose of this movement is to position the three-armed lever I91 so that it will, through a hammer control lever cooperating therewith, lock all the printing hammers against operation during the first cycle of the two cycle operation necessary for taking any kind of total. when the three-armed lever I91 is rocked clockwise in the manner just described, it moves the stud I99 (Fig. 6) to an intermediate position (shown by dot and dash lines in Fig. 15) near the mouth of the opening in the segment I15. This change in the position of the stud I99 in no way effects its relationship with the segment I15, the stud I99 still limiting the extent of movement of the segment I15 just as it does when it is in its normal left hand position shown in Fig. 15. The hammer control lever with which the three-armed lever I91 cooperates during its initial clockwise movement will be later described.

, When the total lever 94 (Fig. 2) is moved to its sub-total taking position the cam disk 229 (Fig. 12), as previously mentioned, is thereby coupled to the gear 299 so that they will operate together and in unison during the operation of the machine. Through such -arrangement the shaft 2 receives a further clockwise movement near the end of the first cycle of operation and, through the train of mechanism previously described, rocks the three-armed lever I91 clockwise to its fullest extent into the right hand posi- -tion shown in Fig. 15. Such movement of the lever I91 carries the stud I99 out of the opening in the segment I15 and clear of the proiection I95 formed thereon. With the stud I99 thus moved to its maximum extent, it no longer exercises any restraint over the movement of the segment I15 by the spring I19. It is thus apparent that during the second cycle of the subtotal taking operation, when the slide I19 (Fig. 9) is shifted to the right, the segment I15 under the action of the spring I19 would follow the slide I19 to the fullest extent of its movement unless prevented from such movement. And under such conditions the return movement of the slide I19 to the left, through its contact with the stud I99 would move the segment I15 its full extent counter-clockwise and would cause the feed roller I99 to give the receipt paper I91 a long feed sufflcient to feed the receipt paper I91 out of the machine.

However, during sub-total operations it is not desired to give the receipt paper I91 such a long feed in order that the amount of tax and the grand total for the complete transaction may subsequently be printed thereon before its issuance from the machine. Therefore the present invention provides means for returning the stud I99 to its normal left hand position (Fig. 15) in the opening formed in the segment I19 shortly after the beginning of the second cycle of a sub-total operation. With the stud I99 thus returned to its normal position, the extent of feed given to the receipt paper I91 is limited to that which it receives during adding operations. The means for accomplishing this result will now be described.

The three-armed lever I91 which carries the stud I99 also carries a stud 919 (Figs. 9, l and 15) projecting through a hole 9' in one of the arms of a bell crank 912 also freely mounted on the shaft 242, The bell crank 912 through the connections 919 and 9" is connected to and moves with the lever I91. When the lever I91 is rocked clockwise near the end of the first cycle of operation, thus carrying the stud I99 out of the opening formed in the segment I15 by the projection I95, the bell crank 912 is likewise rocked clockwise thus placing a stud 919 in the bell crank 912 close to a finger 914 of a lever 915. 1

Shortly after the beginning of the second cycle of the sub-total operation, the bell crank 912 is rocked counter-clockwise and through the pin :10 the lever I91 is likewise rocked counterclockwise thus returning the stud I99 to its normal position. The segment I is then only capable, during the second cycle of operation, of moving the same extent that it does during add-'- ing operations, which results in the receipt paper I91 only being fed a corresponding extent during sub-total operations.

The means for rocking the bell crank 912 counter-clockwise shortly after the beginning of the second cycle of a sub-total operation will now be described. The above mentioned lever 915 is pivoted on a stud 919 carried by the printer side frame I9I and carries a stud 911 projecting through a square opening 919 in the left end of a link 919. The stud 911 is provided with a large head for the purpose of keeping it in the opening 919 in the link 919. The link 919 is pivoted at its right-hand end to an am 999 on a hub 99I freely mounted on a shaft 992 supported by the machine side frame 49 and the printer side frame I9I. Also fast on the hub 99I is an arm 999 carrying a roller 994 cooperating with a raceway 985 in a box cam 999 secured to the printer drive shaft I94. It is thus obvious that during each cycle of operation, the cam 999 is given one complete rotation in a clockwise direction to shift the link 919 first to the left and then back 'to the right to its normal position.

A spring 991 (Fig. 9) constantly tends to draw the left-hand end of the link 919 downwardly so that a notch 999 in the upper wall of the square slot 919 will engage the stud 911 on the lever 915. However, the link 919 is normally held in an elevated or ineffective position, against the tension of the spring 991, by a roller 299 on a yoked arm 999 integral with the arm 249 secured to the shaft 2. It will be recalled that when the total lever 94 is moved to its sub-total taking position, the shaft 2I4 is given a slight clockwise movement, which causes the arm 999 to be lowered slightly but not enough to permit the notch 999 in the link 919 to engage the stud 911. Near the end of the first cycle of a subtotal operation, the shaft 2I4 receives a greater clockwise movement, which causes the arm 999 to withdraw its support from the link 919, thereby freeing the link 919 to the action of the spring 951. It is thus app rent that the link 919 will be drawn downwardly by the spring 991 to permit the notch 989 to engage the stud 311. When the stud 911 is in the notch 999, the link 919, when moved by the cam 995, rocks the lever 915 clockwise, thus causing the finger 914 to contact the stud 919 and rock the bell 'crank 912 and three-armed lever I91 counter-clockwise, thereby returning the stud I99 to its normal position in the opening formed in the segment I15 to effect a control over the segment I 15 to give the strip a short feed only during sub-total operations.

During sub-total operations, it is also necessary that a roller 33I on a lever 332 be moved downwardly to permit the spring 331 to pull the link 319 downwardly into its effective position. This is accomplished by a link 333 and an arm 331 when the total lever 33 is moved to its subtotal taking position, which movement rocks the shaft I33 and a cam arm333 thereon counter-clockwise to position a notch 333 in the arm 335 directly beneath a roller 333 on the lever 332, thus permitting the lever 332 to be lowered by gravity, so that the link 313 can function as above described.

After the sub-total is set up on the indicators and printed on the receipt I31, the total lever 33 is manually returned to its ad position, preparatory to printing the tax on the receipt. The operator then calculates the amount of tax on the sub-total displayed on the indicators, after which the tax is added into the machine and printed on the receipt I31 (Fig. 4). During the addition of the tax the receipt paper receives a short feed, the same as in an adding operation.

Receipt paper feeding mechanism-total operation The operator then moves the total lever 33 to its grand-total taking position, preparatory to printing on the receipt the grand total for the complete transaction, together with the consecutive number, date and other desired data, after which the receipt is automatically fed out of the machine.

Movement of the total lever 33 to its grandtotal taking position, rocks the cam arm 333 clockwise, thereby camming the lever 332 upward to hold the link 313 in its elevated or ineffective position during such operation. Therefore, since the segment I13 is limited in its movement by the stud I33 to give the receipt paper a short feed during the first cycle of operation, the three-armed lever I31 is rocked clockwise, through the cam disk 223 and gear 233 (Fig. 12), near the end of the first cycle of operation, thereby moving the stud I33 to a position outside the opening in the segment I13, into the right-hand position shown in Fig. 15. The segment I13 thus free of the stud I33, immediately following the printing on the receipt I31 during the second cycle of operation of the grand total, consecutive number, date and other desired data, actuates the feed roller I33 to give the receipt a long feed to place it in position to be taken from the machine by the operator.

Receipt printing hammers There are three impression hammers 213, 21I and 212, for printing the issuing receipt. The hammer 213 prints the consecutive number and the words Total shown above. The hammer 21I prints the electro wording and the date and the hammer 212 prints the items, sub-total and total. These hammers are all loosely mounted on a stud 213 (Figs. 6 and 7) supported by the printer frame I3I. A bail 213 (Fig. 7), extending between two arms 213 (only one of which is shown), on the stud 213, is provided to actuate the hammers. The right-hand arm 213 has secured thereto an arm 213 connected to an operating arm 211 (Fig. 7) by a link 213. The arm 211 is pivoted on a shaft 213 and has a nose 230 cooperating with a cam 23l fast on the printer drive shaft I33.

The bail 213 overlies an arm 232 of a hammer operating lever 283 pivoted on the stud 213. A

spring 233 (Fig. 7) is connected to the operating lever 233 and acts to hold the arm 232 against the underside of the bail 213, the bail in turn being limited in its movement by an extension 233 on the lever 211 striking the underside of a block 23l fast to the side of the printer side frame I 3|. Thus, this block 23l determines the normal position of the lever 211, link 213, arms 213 and 213, bail 213 and operating lever 233.

A spring 232 normally holds a stud 233 on the item printing hammer 212 against the underside of an extension 233 of the operating lever 233.

When the printer drive shaft I33 is rotated clockwise during an operation of the machine (Fig. 7), a lobe 233 on the cam 23l strikes the nose 233 and earns the lever 211 clockwise, and the link 213 rocks the arms 213 and 213 and bail 213 clockwise. Clockwise movement of the bail 213 rocks the lever 233 clockwise and through the spring 232 rocks the hammer 212 clockwise During the rotation of the cam 23l, when the lobe 233 passes from beneath the nose 233, the lever 211 is rocked rapidly counter-clockwise by the powerful spring 233 until the extension 233 thereon strikes the block 23l. The quick counter-clockwise movement of the lever 211 is transmitted to the hammer 212, and the hammer is carried forward on. its own momentum, when the lever 211 is stopped by the block 233, thus causing an impression platen 233 (Fig. 6) carried by the hammer 212 to make a printed record on the strip I31 from the type wheels I23. The stopping of the lever 211 also stops the link 213, arms 213, bail 213 and operating lever 233. Movement of the hammer 212 is permitted by the stretching of the spring 232. After the impression is taken, the spring 232 returns the hammer 212 to its normal position, as shown in the drawings.

The printing hammer 213 (Fig. 6) which prints the consecutive number and the words Total shown above" on the receipt, is actuated by the cam 23l in the same manner as just described for the item printing hammer 212. The hammer 213 has associated therewith an operating lever 233, a rear arm 233 of whichcooperates with the bail 213. A stud 233 on the arm 213 is held in contact with an arm 231 of the lever 233 by a spring 233.

Actuation of the bail 213 by the lobe 233 on the cam 23l results in the actuation of the operating lever 233 to cause the hammer 213 to be operated in the same manner as above described for the item hammer 212, thus causing an impression platen 231 carried by the hammer 213 to take an impression from a set of consecutive number printing wheels (not shown) and certain data, namely "Total shown above" from an elelctroplate 233 supported by the printer frame I3 However, the hammers 212 and 213 are subject to controls hereinafter described which may prevent tripping of the hammers by the cam 23l.

A separate train of mechanism is provided for actuating the hammer 21I, which prints the date and other data from the electroplate 233 on the receipt. This train of mechanism is the same in principle of operation as that for actuating the hammers 213 and 212, described above.

The printing hammer "I (Fig. 6) is actuated by a cam 233, which cooperates with a lever 233 connected by a link 333 with an arm 333 of one lever of a pair of levers 331 freely mounted on the shaft 219. A ball 999 connectsthe pair of levers 991 (only one of which is shown) and overlies a shoulder formed on the printing hammer 21I. A spring, not shown but like the springs 299 and 292, maintains the shoulder on the printing hammer 2" in contact with the bail 999.

When the cam 299 is rotated clockwise. it actuates the link 999, arm 999 and levers 991 to rock the bail 999 clockwise against the tension of a powerful spring 999, in the same manner that it does the bail 219 associated with the hammers 212 and 219. The hammer 2" is forced by a spring like 299 and 292 to follow the bail 999 in its clockwise movement until the cam 299 passes from beneath the end of the operating lever 299 whereupon the levers 991 and hail 999 are rocked rapidly counter-clockwise by the powerful spring 999. The hammer 21I is thus rocked counter-clockwise to take an impression by platens 9I9 and 9Il carried thereby from the electroplate 299 and date type wheels (not shown) on the receipt strip I91. After the impression is made, the hammer 21I is restored to its normal position by means of its spring in a manner similar to that of the hammers 219 and 212.

The ball 999 (Fig. 6) has formed thereon a flange 9I2 cooperating with a latch 9I9 mounted on a rod 9, suitably supported in the printer side frame I9I, for the purpose of preventing any rebound movement of the hammer 21I after it has been rocked counter-clockwise to take an impression. A spring 9I9 normally urges the latch 9I9 in a clockwise direction so that a hook 9I9 will embrace a pin 9I1 carried by the hammer 21I and restrain it against movement out of its normal position. When the hammer 21I is rocked clockwise by the bail 999 and levers 991, preparatory to taking an impression, the flange 9I2 engages a projection 9I9 on the latch and rocks the latch counter-clockwise to release the hammer 21I for operation.

Detail printing hammers The impression is made upon the record strip I99 by a platen 929 carried by an impression hammer 929 (Figs. 6 and 8) pivoted on the rod 219. A spring 929 normally holds a stud 921 on the impression hammer 929 against the upper side of an extension 929 of an impression hammer operating lever 929 pivoted on the rod 219. A bail 999 extending between two arms 99I (only one of which is shown) loosely mounted on the rod 219 is provided to actuate the operating lever 929 and the impression hammer 929. The righthand arm 99I has secured thereto an arm 992 loosely mounted on the rod 219.

The bail 999 underlies an arm 999 of the hammer operating lever 929. A powerful spring 999 is connected to the lever 929 and acts to hold the arm 999 against the bail 999, the bail 999 in turn being limited in its movement by an extension 999 on the arm 99I striking a stationary rod 999 supported bythe printer side frame I9I. Thus the rod 999 determines the normal position of the lever 929 and ball 999.

When the printer drive shaft I99 is rotated clockwise during an operation of the machine, a lobe 991 on a cam 999 fast to the shaft I99 strikes an edge 999 of the arm 992 and earns the arm 992, bail 999 and lever 929 counter-clockwise. Counter-clockwise movement of the lever 929, through the spring 929, rocks the impression hammer 929 counter-clockwise. When the lobe 991 clears the edge 999 of the arm 992, the lever 929 is rocked rapidly clockwise by the powerful spring 999 until the extension. 999 of the arm 992 strikes the stationary rod 999. The quick clockwise movement of the lever 929 is transmitted to the impression hammer 929, and the hammer 929 is carried still further upward by its own momenturn, when the lever 929 is stopped by the rod 999. It is during the movement of the hammer 929 after the lever 929 has been stopped that the hammer 929 takes an impression from the lower set of type characters on the printing wheels I99. The movement of the hammer 929 after lever 929 has been stopped is permitted by the stretching of the spring 929. After the impression is taken the spring 929 returns the hammer 929 to its normal position, as shown in Fig. 8.

The cam 999 (Fig. 8), in addition to the lobe 991, is shown as having two other lobes, which lobes are used in giving the hammer 929 two additional actuations during each operation of the machine for the purpose of printing in two different places on an inserted slip. Inasmuch as the inserted slip printing feature forms no part of the present invention, it is unnecessary for the cam 999 to have more than the one lobe 991, which causes a single actuation of the hammer 929 during each operation of the machine to print on the record strip I99.

Control means for disabling printing hammers By means hereinafter described, the hammers 219 and 21I are normally disabled and are so held during adding operations. The hammers 212 and 929 are normally in position to be tripped during adding operations.

Means is provided under control of the total lever 99 for disabling the printing hammers 212 and 929 during the first cycle of either sub-total or grand-total taking operations the other two hammers 219 and 2H remaining normally disabled during such cycles.

Mechanism, amply illustrated and described in the above mentioned Shipley Patent No. 1,865,147, is provided which, under control of the total lever 99 (Fig. 2) causes the machine to operate continuously through two cycles of operation when a sub-total or grand-total is to be taken from a selected totalizer.

Such disabling of all of the printing hammers during the first cycle of either a sub-total or grand-total operation is customary in machines of the type herein referred to, as illustrated and described in the before mentioned Brand Patent No. 1,993,793. It was also customary in such machines to release all of the printing hammers, during the second cycle of such operations, to print on the receipt paper and record strip.

However, the present invention contemplates, in addition to disabling all of the printing hammers during the first cycle of a sub-total operation, also disabling the printing hammers 219 and 2" (Fig. 6) during the second cycle of such subtotal operation, and then releasing said hammers 219 and 2H for operation during the second cycle of a grand-total operation.

The purpose of such an arrangement is to prevent the hammers 219 and 2", which it will be recalled print the consecutive number, date and of a hammer control lever 346 (Figs. 6, 9, 13 and 14), journaled on the largest type carrier sleeve I48, carrying at its lower end a flange 341- and at its upper end a flange 360 having an extension 36I, while extending from its right hand side is a projection 366. The flanges 341 and 360, extension I and projection 366 on the hammer control lever 346 disable the printing hammers 324, 210, 212 and 2", respectively, when the lever 346 is moved by the total lever 34 to certain of its various positions of adjustment. The manner in which this result is accomplished will now be described.

The flange 341 cooperates with a stud 343 (Fig. 6) on an arm 343 secured to the record strip printing hammer 324 to disable that hammer. The extension 36I (Figs. 13 and 14) on the flange 350 cooperates with a stud 362 projecting laterally from an arm 363 secured to the amount printing hammer 212 for disabling such hammer. The flange 350 cooperates with a stud 364 on an arm 355 secured to the consecutive number and special data printing hammer 210 for disabling this hammer; and the projection 336 contacts a stud 351 on an arm 353 connected by a bail 363 to an upwardly extending arm 360 having a notch 362 adapted to engage a stud 363 on the date and special data printing hammer 2". The projection 356 by contacting the stud 361 holds the arm 360 in the position shown (Fig. 6) against the action of a spring "I to disable the date and special data printing hammer 211.

The extension "I which cooperates with the stud 352 on the arm 363 of the amount printing hammer 212 .is shorter than the oppositely extending flange 350 cooperating with the stud 364 on the arm 355 of the consecutive number and special data printing hammer 210, the two studs 362 and 364 being spaced apart from each other, and extending laterally toward each other. The hammer control lever 346 extends into the space between the two studs 362 and 364 on the parallel printing hammers 212 and 210, respectively.

When the total lever 34 is in its "add" positlon (Fig. 2), the hammer control lever 346 is 80 positioned that the flange 330 cooperates with the stud 364 on the arm 366 of the consecutive number and special data printing hammer 213, and the projection 366 contacts the stud 361 to cause the notch 362 to engase the stud 363 on the date and special data printing hammer 21l. The'hammers 210 and 2" are thus disabled during adding operations. The W of having these hammers thus disabled during adding operations is to prevent printing on the receipt the date, consecutive number and special data, which it is not desired to have printed until after a grand total for the complete transaction Is printed on the receipt.

The position which the hammer control lever 346 assumes during adding operations is such that the flange 341 does not cooperate with the stud 348 on the arm 343 secured to the lower or record strip printing hammer 324, nor does the extension 351 on the flange 330 cooperate with the stud 352 on the arm 363 secured to the amount printing hammer 212. It is thus apparent that during adding operations only the. amounts will be printed on the-record strip I33 and receipt I31 by the hammers 324 and 212, respectively.

The manner in which the total lever 34 controls the hammer control lever 346 will now be described. When the total lever 34 is moved to its sub-total" position, the slot 233, through the mechanism heretofore described, causes the shaft 2I4 and shaft 242 to be rocked slightly clockwise. Such movement of the shaft 214 couples the cam disk 223 to the gear 233, thereby preparing the machine for a two cycle operation. Through the flexible drive connections 246 and 241 (Figs. 10 and 11) this slight clockwise movement of the shaft 242 is transmitted to the three-armed lever I31, which, through a stud 404 thereon coacting with a notch 406 formed in the hammer control lever 346, rocks said lever slightly counter-clockwise to disable all of the printing hammers during the first cycle of a subtotal operation.

Near the end of the first cycle of the subtotal operation, the shaft 242, through the cam disk 223 and gear 233, receives a further clockwise movement and, through the three-armed lever I31, rocks the hammer control lever 346 further counter-clockwise to release all of the printing hammers for operation during the second cycle of operation, as is customary in such types of machines.

However, as before mentioned,'it is not desired to have the consecutive number and special data printing hammer 210 and the date and special data printing hammer 2" print during sub-total operations. Therefore, the link 313, when rocked toward the left shortly after the beginning of the second cycle of the sub-total operation, as previously described, rocks the lever 315 clockwise. The finger 314 on the lever 315 contacts the stud 313 and rocks the bell crank 312 and lever I31 counter-clockwise, thereby rocking the hammer control lever 346 clockwise to disable the consecutive number and special data printing hammer 210 and the date and special data printing hammer 21I during sub-total operations.

When the three-armed lever I31 is rocked counter-clockwise shortly after the beginning of the second cycle of the sub-total operation, to position the hammer control lever 346 to disable the printing hammers 210 and 2H, means is provided for holding the lever I31 in its moved position to prevent premature movement therefrom until the end of the second cycle of the sub-total operation. The hammer control lever 346 is thus prevented from being moved to release the printing hammers 210 and 2" during the second cycle of the sub-total operation,

The means for accomplishing this result consists of a latch 406 (Figs. 6 and 16) pivoted on a stud 401 in the printer side frame I3I. When the lever I31 is rocked counter-clockwise shortly after the beginning oi the second cycle of a subtotal operation, it is moved slightly beyond its normal position, thereby carrying the stud 404 thereon above a shoulder 400 formed on the latch 406. When this occurs the latch 406 is rocked clockwise by a spring 403 to position the shoulder 403 directly beneath the stud 404, thereby preventing clockwise movement of the lever I31 until the end of the second cycle of a sub-total operation.

Clockwise movement of the latch 406 by the spring 403 is normally prevented by an angularly disposed finger 4I0 formed on the latch 406 contacting a stud 4 carried by a pitman H2. The pitman H2 is supported at its left-hand end by a stud 3 on the printer side frame I3I projecting through a clearance slot 4 in the pitman. At its opposite end the pltman 4 I2 is slidably mounted on the printer drive shaft I34. A pair of cams 4i! and 6 fast on the shaft I34 cooperate with a pair of rollers 411 and H3, respectively,

and normally hold the pitman 2 in its normal position. The roller "1 is mmmted on the side of the pitman 2, while the roller I is carried on a stud lit mounted near the upper end of a spring-actuated lever "I pivoted to the pitman M2. The roller 3, through the spring-actuated lever 42., is held in cooperative relationship with thecamlitatalltlmes. 'Ihepurposeof the spring-actuated lever 42. is not pertinent to the present invention and therefore its function is not described.

Shortly after the beginning of each cycle of operation of the machine, the cams I and Ill shift the pitman l2 to its extreme right-hand position, thereby moving the stud ill in a horizontal plane. The finger lll under the action of the spring 9 follows the stud II when released by the lever I31.

Since it is only during the second cycle of a sub-total operation that the three-armed lever I91 is rocked counter-clockwise slightly beyond its normal position by the mechanism previously described, it is only at such time that the stud 404 on the lever 'll'l is moved above the shoulder 408 on the latch 406. Therefore, it is only during the second cycle of a sub-total operation that the shoulder 40! is moved by the spring 0 suillciently clockwise to position it directly beneath the stud 404 to hold the three-armed lever I31 and its associated parts in their moved position. thereby preventing the printing hammers 21. and 2'" from being released for operation during sub-total operations. Near the end of the second cycle of the sub-total operation, the cams 4|! and 6 shift the pitman "2 back toward the left to its normal position, whereupon the stud lll cooperates with the finger ill to rock the latch 05 counter-clockwise, thereby withdrawing the shoulder 408 from beneath the stud I at the end of the operation. The three-armed lever I31 and its associated parts are thus free to be moved clockwise and counter-clockwise during subsequent operations.

When the total lever 34 is moved from its add position to its "grand total position, it positions the hammer control lever 346 to disable all of the printing hammers during the first cycle of such operation in the same manner as during "subtotal" operations. In addition, it positions the cam arm 395 (Fig. 10) so that it will cause the lever 392 to hold the link 313 in its elevated or ineffective position. Therefore, when the threearmed lever I9! is rocked clockwise near the end of the first cycle of a grand total operation, through the cam disk 229 and gear 233, thereby positioning the hammer control lever I to release all of the hammers for operation, the link 319 having been rendered ineffective will have no influence on the same. Thus all of the printing hammers are released to print on the receipt I31 and record strip I38, during the second cycle of a grand total operation, immediately after which the receipt is fed out of the machine.

While the form of mechanism herein shown and described is admirably adapted to fulfill the objects primarily stated, it is to be understood that it is not intended to confine the invention to the one form or embodiment herein disclosed, for it is susceptible of embodiment in various forms all coming within the scope of the claims which follow.

What is claimed is:

1. In a machine of the class described, the combination of record material feeding mechanism; a manipulative device for preparing the machine '1 1 for sub-total and grand-total taking operations;

and means including a member cooperable with the feeding mechanism and means for shifting the member different extents under control of said device for causing said mechanism to feed the record material a different distance durinl sub-total taking operations from that during grand-total taking operations.

2. In a machine of the class described, the combination of record material feeding mechanism: a total taking control device to control the machine to take grand totals and sub-totals; and means including a member moved diil'erent distances under control of said device in grand total and sub-total operations and cooperable with said feeding mechanism to control said feeding mechanism to feed the record material a short distance during sub-total operations and a long distanc during grand-total operations.

3. In a machine adapted to make different kinds of total taking operations, the combination of record material feeding means; a total taking control device; and means controlled by said device and variably cooperable with the feeding means in different kinds of total taking operations to cause the record material to be fed different distances during different kinds of total taking operations. I

4. In a machine of the class described, the combination of record material feeding mechanism; and means including an element coacting with the feeding mechanism and operable different extents to control the mechanism to feed the record material a certain distance during adding operations, a longer distance during sub-total operations, and a still greater distance during grand total operations.

5. In a machine adapted to print items, subtotals and grand totals, the combination of record material feeding mechanism adapted to feed the record material a certain distance during adding operations; means for controlling said mechanism to allow said mechanism to feed the record material a predetermined distance during grandtotal operations; said means being operable in sub-total operations; and a device jointly copperable with said means in sub-total operations to modify the control by said means so that said mechanism will feed the record material only a portion of said predetermined distance during sub-total operations.

6. In a machine of the class described, the combination of record material feeding mechanism; a sub-total and grand total control device; means under control of said device for controlling the feeding mechanism during grand total taking operations; said means being operable under control of said device in sub-total taking operations; and mechanism effective during sub-total taking operations and jointly operable with said means to modify the control exercised by said means to control the operation of the feeding mechanism to produce a different feed in sub-total operations from that in grand total operations.

7. In a machine adapted to print different kinds of totals, the combination of record material feeding mechanism; and means operable differently in different kinds of total taking operations and cooperable with the feeding mechanism to cause said feeding mechanism to feed the record material one distance when taking one kind of total and a greater distance when taking another kind of total.

8. In a machine of the class described, the.

combination of record material feeding mechanism; a total control device; and means intermediate said mechanism and said device and differently. cooperable with the feeding mechanismtocauseashortfeedtobegiven therecord material during sub-total operations and a long feed during grand total operations.

9. In a machine adapted to print sub-totals and grand totals, the combination of record material feeding mechanism; a gear segment for actuating said mechanism; a total control lever settable to control sub-total and grand total 017- erations; and means variously shifted under control of said lever and coasting with the segment to control the extent of movement of said legment to cause said mechanism to feed the record material a short distance during sub total operations and a long distance during grand total operations.

10. In a machine of the class described, the combination of record material feeding mechanism; a shiftable member; a total control device to control the machine for different kinds of total operations; and means under control of said device for positioning said shiftable member tocontrol said mechanism to feed the record material diiferent distances during different kinds of total taking operations.

11. In a machine adapted to print sub-totals and grand totals, the combination of record material feeding mechanism; a reciprocating member; a cam arm; a total control device adapted to adjust said cam arm; and means intermediate said cam arm and said reciprocating member to render said reciprocating member effective in sub-total operations whereby said member controls the feeding mechanism to feed the record material a different distance during sub-total operations than during grand total operations.

12. In a machine adapted to print items, subtotals and grand-totals,- the combination of record material feeding mechanism operable to feed the material short, intermediate, and greater dis stances during various operations; a .gear segment for actuating said mechanism; a movable member normally cooperating with said segment to cause said mechanism to feed the record material a short distance during adding operations; means for moving said member out of cooperative relation with said segment to cause said mechanism to feed the record material a greater distance during grand total operations; said means also being operable insub-total operations; and means for returning said member into cooperative relation with said segment during sub-total operations to cause the mechanism to feed the record material an intermediate distance during sub-total operations.

13. In a machine of the class described, the combination of record material feeding mechanism; a gear segment for actuating said mechanism; a movable member normally in cooperative relation with said mechanism; a total control device to control the machine for total and sub-total operations; and means under control of said device for controlling the movement of said member to cause the feeding mechanism to feed the record material a. short distance during subtotal operations and a long distance during grand total operations.

14. In a machine adapted to make two-cycle operations to print grand totals and sub-totals, the combination of record material feeding mechanism; a gear segment for actuating said mechanism; operating mechanism for said segment;

a movable member normally cooperating with said segment; means-for moving said member out or cooperative relation with said segment during the ilrst cycle of a two-cycle grand total operation to allow the se ment to actuate said mechanism to feed the record material a long distance during the second cycle otgrand total operations; saidmeansalsomovingthememberduringthe first cycle of a two-cycle sub-total operation;

and a device rendered effective during a sub-totalv operation for automatically returning said member into cooperative relation with said segment during the second cycle of a two-cycle sub-total operation to allow the segment to actuate said mechanism to feed the record material a short distance during said sub-total operation.

15. In a machine operable in two cycle operations to print sub-totals and grand totals. the

combination of record material feeding mecha-' nism for feeding the record material different distances depending upon the kind of total printed; a total control device; and means controlled by the device for controlling the extent of the feedof the record material, said means including a reciprocating member which is operable during each cycle of the two-cycle operations and selectively effective to exert a control on the feeding means; and a plurality of members under control of saiddevice and adapted to cooperate with the reciprocating member to control the effectiveness of the same.

16. In a machine adapted to print sub-totals and grand totals, the combination of record material feeding means; an adjustable means cooperating with the feeding means to control the same to feed the record material different distances for different kinds of total operations; a total control device; a reciprocating member having an effective position and an ineilective position; rockable means adapted to be operated by the reciprocating member when the latter is in effective pofltion to control said adjustable means; and a plurality of means under control of said device to determine when the reciprocating member is to be effective to operate said rockable means and when it is to be ineffective.

17. In a machine adapted to print sub-totals and grand totals, the combination of record material feeding means; an adjustable means cooperating with the feeding means to control the same to feed the record material difl'erent distances for diiferent kinds of total operation; a total control device; a reciprocating member having an effective position and an ineilective position; rockable means adapted to be operated by the reciprocating member when the latter is in effective positionto control said adjustable means; a pluralityof means each being normally in an effective position to prevent the reciprocating member from being moved into its effective position; means under control oi said- 

